US2014034499A1PendingUtilityA1

Microfluidic control apparatus and operating method thereof

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Assignee: CRYSTALVUE MEDICAL CORPPriority: Aug 20, 2010Filed: Oct 7, 2013Published: Feb 6, 2014
Est. expiryAug 20, 2030(~4.1 yrs left)· nominal 20-yr term from priority
B01L 2300/089B01L 2400/082B01D 21/0009B01L 2400/0418G01N 35/1095B01L 3/502761B01L 3/50273B01L 2200/14B01L 2300/0816
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Claims

Abstract

A microfluidic control apparatus operating method is disclosed. The microfluidic control apparatus operating method is applied in a microfluidic control apparatus, and the microfluidic control apparatus includes a photoconductive material layer and a flow passage. The microfluidic control apparatus operating method includes steps of (a) when a light with a specific optical pattern is emitted toward the photoconductive material layer, at least three virtual electrodes being formed on the photoconductive material layer according to the specific optical pattern; (b) when the specific optical pattern changes, the at least three virtual electrodes also changing to generate an electro-osmotic force to control a moving state of a microfluid in the flow passage.

Claims

exact text as granted — not AI-modified
What is claimed is: 
     
         1 . A microfluidic control apparatus operating method applied in a microfluidic control apparatus, the microfluidic control apparatus comprising a flow passage and a photoconductive material layer, the method microfluidic control apparatus operating comprising steps of:
 (a) when a light with a specific optical pattern is emitted toward the photoconductive material layer, at least three virtual electrodes being formed on the photoconductive material layer according to the specific optical pattern; and   (b) when the specific optical pattern changes, the at least three virtual electrodes also changing to generate an electro-osmotic force to control a moving state of a microfluid in the flow passage;   wherein, the at least three virtual electrodes comprise a first virtual electrode, a second virtual electrode, and a third virtual electrode; the second virtual electrode and the third virtual electrode are disposed at two sides of the first virtual electrode, and a specific ratio is existed among the distance between the first virtual electrode and the third virtual electrode, the width of the first virtual electrode, the distance between the first virtual electrode and the second virtual electrode, and the width of the second virtual electrode.   
     
     
         2 . The microfluidic control apparatus operating method of  claim 1 , wherein an Electro-Osmotic Flow (EOF) mechanism is used to change the position of the specific optical pattern to adjust a forming ratio of the at least three virtual electrodes formed on the photoconductive material layer to control the microfluid. 
     
     
         3 . The microfluidic control apparatus operating method of  claim 1 , wherein the specific ratio existed among the distance G 1  between the first virtual electrode and the third virtual electrode, the width W 1  of the first virtual electrode, the distance G 2  between the first virtual electrode and the second virtual electrode, and the width W 2  of the second virtual electrode is 1:5:1:3. 
     
     
         4 . The microfluidic control apparatus operating method of  claim 1 , wherein under the condition of maintaining the voltage and the frequency unchanged, the microfluidic control apparatus controls a moving direction or a rotation direction of the particles in the microfluid, so that the microfluid forms moving states of driving, mixing, concentrating, separating, and swirl. 
     
     
         5 . The microfluidic control apparatus operating method of  claim 1 , wherein the photoconductive material layer is formed by a material having resistance varied with different lights, the photoconductive material layer is charge generating layer material Titanium Oxide Phthalocyanine (TiOPc), amorphous silicon (a-Si), or polymer.

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